Food Habits of Charadriiform Birds During Peak Migration Through Eastern South Dakota

The shorebirds, Order Charadriiformes, are very important organisms as they make up a great proportion of the summer biomass in arctic regions. Spring migration routes of many species of shorebirds carry them through eastern South Dakota where· lakeshores and temporary ponds are crucial stopover points. At these stopover points, the birds feed on various organisms which will supply them with the energy needed for completion of migration and for breeding. This is a study of the migratory schedules and feeding ecology of shorebirds migrating through eastern South Dakota during the spring migrations of 1985 and 1986. It is a part of the ongoing shorebird banding project conducted by Dr. John Haertel of the Biology Department at South Dakota State University. The major objectives of this study are: 1) to determine the peaks of shorebird migration through eastern South Dakota; 2) to determine the food items taken on migration stopover; and 3) to determine if the birds are selecting for specific food items. Information from studies based in South Dakota will add to the overall picture of migration across the United States

The Turtle Head Immobilization System (THIS): A Tool for Faster and Safer Handling and Processing of Aggressive Turtle Species

The turtle head immobilization tool (THIS) is an efficient and cost effective tool to aid in the processing of large, aggressive turtles such as the Eastern Snapping Turtle (Chelydra serpentina). THIS aids in the reduction of aggressive behaviors by calming the animal during processing and minimizing injuries to the turtle and handlers. This simple tool also streamlines the processing itself, by allowing researchers to focus on measurements and markings, instead of having to maintain the constant vigilance often needed to work safely around these animals

The Turtle Head Immobilization System (THIS): A Tool for Faster and Safer Handling and Processing of Aggressive Turtle Species

The turtle head immobilization tool (THIS) is an efficient and cost effective tool to aid in the processing of large, aggressive turtles such as the Eastern Snapping Turtle (Chelydra serpentina). THIS aids in the reduction of aggressive behaviors by calming the animal during processing and minimizing injuries to the turtle and handlers. This simple tool also streamlines the processing itself, by allowing researchers to focus on measurements and markings, instead of having to maintain the constant vigilance often needed to work safely around these animals

The North American Freshwater Turtle Research Group (NAFTRG): An undergraduate research experience (URE) and citizen scientist project

Researchers today understand the importance of incorporating undergraduate research experiences (URE) and citizen-science methods into data collection and long-term research projects. The North American Freshwater Turtle Research Group (NAFTRG) is an example of a project in which both methods are implemented. The NAFTRG conducts long-term studies on turtle populations in seven state park springs in Florida and the largest freshwater spring in Texas. Although the study began as an undergraduate biology class, it has expanded throughout the years into a study that many parks and researchers rely upon for important data on turtle populations and for information that helps manage the stability of ecosystems. Through the use of UREs, the research investigators are enabling undergraduates to gain valuable research experiences while maintaining a volunteer base that has a vested interest in the study itself. Students from Pennsylvania State University, University of North Florida, Peninsula College, Freed-Hardeman University, and Western Washington University have chosen to participate in the study. Many of these students have volunteered additional time and efforts during subsequent research trips. A project of this nature enables students to see the importance of ecosystem awareness. Through the use of citizen science, investigators can form a large volunteer base while incorporating sophisticated ecological methodologies and furthering coonservation efforts. Many participating citizen scientists have jobs unrelated to the sciences; they volunteer their time because they understand the importance of the group’s objectives and are willing to support them with their time and energy. Our current volunteer base receives further support from local zoos, aquariums, amusement parks, and the public. Based on standardized values for volunteer work, citizen scientists and donations from governmental and non-governmental organizations have contributed approximately one million dollars to this project. Citizen science is helping to bridge the gap between the general public and the scientific community by allowing the two to work together in monitoring, managing, maintaining, and understanding the ecological issues around us. &nbsp

The Turtle Head Immobilization System (THIS): A Tool for Faster and Safer Handling and Processing of Aggressive Turtle Species

The turtle head immobilization tool (THIS) is an efficient and cost effective tool to aid in the processing of large, aggressive turtles such as the Eastern Snapping Turtle (Chelydra serpentina). THIS aids in the reduction of aggressive behaviors by calming the animal during processing and minimizing injuries to the turtle and handlers. This simple tool also streamlines the processing itself, by allowing researchers to focus on measurements and markings, instead of having to maintain the constant vigilance often needed to work safely around these animals

Anomalous Diffusion in Infinite Horizon Billiards

We consider the long time dependence for the moments of displacement < |r|^q > of infinite horizon billiards, given a bounded initial distribution of particles. For a variety of billiard models we find ~ t^g(q) (up to factors of log t). The time exponent, g(q), is piecewise linear and equal to q/2 for q2. We discuss the lack of dependence of this result on the initial distribution of particles and resolve apparent discrepancies between this time dependence and a prior result. The lack of dependence on initial distribution follows from a remarkable scaling result that we obtain for the time evolution of the distribution function of the angle of a particle's velocity vector.Comment: 11 pages, 7 figures Submitted to Physical Review

Active megadetachment beneath the western United States

Geodetic data, interpreted in light of seismic imaging, seismicity, xenolith studies, and the late Quaternary geologic history of the northern Great Basin, suggest that a subcontinental-scale extensional detachment is localized near the Moho. To first order, seismic yielding in the upper crust at any given latitude in this region occurs via an M7 earthquake every 100 years. Here we develop the hypothesis that since 1996, the region has undergone a cycle of strain accumulation and release similar to “slow slip events” observed on subduction megathrusts, but yielding occurred on a subhorizontal surface 5–10 times larger in the slip direction, and at temperatures >800°C. Net slip was variable, ranging from 5 to 10 mm over most of the region. Strain energy with moment magnitude equivalent to an M7 earthquake was released along this “megadetachment,” primarily between 2000.0 and 2005.5. Slip initiated in late 1998 to mid-1999 in northeastern Nevada and is best expressed in late 2003 during a magma injection event at Moho depth beneath the Sierra Nevada, accompanied by more rapid eastward relative displacement across the entire region. The event ended in the east at 2004.0 and in the remainder of the network at about 2005.5. Strain energy thus appears to have been transmitted from the Cordilleran interior toward the plate boundary, from high gravitational potential to low, via yielding on the megadetachment. The size and kinematic function of the proposed structure, in light of various proxies for lithospheric thickness, imply that the subcrustal lithosphere beneath Nevada is a strong, thin plate, even though it resides in a high heat flow tectonic regime. A strong lowermost crust and upper mantle is consistent with patterns of postseismic relaxation in the southern Great Basin, deformation microstructures and low water content in dunite xenoliths in young lavas in central Nevada, and high-temperature microstructures in analog surface exposures of deformed lower crust. Large-scale decoupling between crust and upper mantle is consistent with the broad distribution of strain in the upper crust versus the more localized distribution in the subcrustal lithosphere, as inferred by such proxies as low P wave velocity and mafic magmatism